تعداد نشریات | 161 |
تعداد شمارهها | 6,532 |
تعداد مقالات | 70,504 |
تعداد مشاهده مقاله | 124,123,756 |
تعداد دریافت فایل اصل مقاله | 97,231,893 |
ساختارهای انعطافپذیر؛ راهکاری در جهت کاهش معضلات عملکردی پوستههای متحرک | ||
نشریه هنرهای زیبا: معماری و شهرسازی | ||
مقاله 14، دوره 24، شماره 2، تیر 1398، صفحه 39-48 اصل مقاله (3.81 M) | ||
نوع مقاله: مقاله پژوهشی | ||
شناسه دیجیتال (DOI): 10.22059/jfaup.2019.258891.672029 | ||
نویسندگان | ||
کتایون تقی زاده* 1؛ محمدرضا متینی2؛ الناز کاکوئی3 | ||
1دانشکده معماری - دانشگاه تهران | ||
2دانشکده معماری، دانشگاه هنر | ||
3کارشناس ارشد تکنولوژی معماری، پردیس هنرهای زیبا، دانشگاه تهران، ایران. | ||
چکیده | ||
به منظور دستیابی به یک معماری پاسخگو که بتواند با شرایط پیرامونیاش سازگار باشد، رویکرد غالب آن است که معماران، طراحان و مهندسان سازه، تمرکز خود را بر روی طراحی و ساخت پوستههای ساختمانی متحرک متشکل از اعضای صلب و مفاصل مکانیکی قرار میدهند. گرچه ممکن است این شیوه مزایایی به همراه داشته باشد، اما میتواند با ایجاد مشکلات و ضعفهایی چون شکست و گسیختگی ناشی از تنشهای بالا در مفاصل، منجر به هزینه بالای تعمیر و نگهداری شود. هدف از تحقیق پیشرو، بهرهگیری از پتانسیل مکانیزمهای انعطافپذیر در طراحی و ساخت نماهای متحرک است که بدین منظور، پس از دستهبندی کاربرد مکانیزمهای انعطافپذیر در معماری در دو سطح (سطح نخست: جایگزینی آنها با مکانیزمهای صلب-پیکر و سطح دوم: طراحی مکانیزمی یکپارچه)، تمرکز این مقاله بر روی سطح نخست است. دستآورد این سطح که در قالب سه زیردسته ((1) حرکتهای انتقالی، (2) دورانی و (3) انتقالی- دورانی در مفاصل انعطافپذیر) و به روش شبیهسازی مورد بررسی قرار گرفت، طراحی، شبیهسازی رایانهای و ساخت سه مدل فیزیکی از پوستههای متحرک ساختمانی است که غالب مزایای ساختارهای انعطافپذیر چون یکپارچگی ساختار، کاهش تعداد اعضا و وزن سازه، کاهش چشمگیر تنش در مفاصل، هزینه تعمیر و نگاهداری و در نهایت توجیه اِقتصادی طرح را به همراه دارد. | ||
کلیدواژهها | ||
پوستههای ساختمانی متحرک؛ مکانیزم انعطافپذیر؛ مکانیزم صلب-پیکر؛ مکانیزم انعطافپذیر دوپایا | ||
عنوان مقاله [English] | ||
Compliant Mechanisms; an Approach Leading to Functional Deficiencies Reduction in Kinetic Skins | ||
نویسندگان [English] | ||
Mohammadreza Matini2؛ Elnaz Kakouee3؛ | ||
2School of Architecture, Honar University | ||
3Master of Technology in Architecture, Faculty of Fine arts, Tehran University, Iran. | ||
چکیده [English] | ||
In order to achieve a responsible architecture, which can adapt itself with surrounding conditions, the major approach is that architects, designers and structural engineers concentrate on design and construction of kinetic structures consisted of rigid bodies and mechanical joints. Although this method may have some advantages in, but for architectural applications, which increasingly need their own solutions in each project, it can have deficiencies such as failures and ruptures due to high tensions in joints as well as high costs in repairing and maintenance. Kinetic skins in architecture are usually designed and executed in negligible numbers and customized for each new project. In architecture as other fields of engineering, kinetic structures are usually based on the principles of the basic construction that rigid bodies are connected with mechanical joints. However, there is a difference between moving structures in the machine industry and architecture. The high weight of these structures with mechanical elements leads to higher weights, which can cause lots of deficiency in earthquakes. In addition, the construction of complex designs that are often desirable for architects and designers is only due to the complexity of mechanisms and considerable increasing in the number of elements. In other words, along with all the advantages of structures made with rigid elements, which cannot be ignored, disadvantages of this design and construction also have to be considered. Most of challenges due to rigid mechanical structures seem to be caused by animated joints; high stresses, fractures and structural failures often occur in these parts of structures. The aim of this research is to use the potential of compliant mechanisms in design and construction of kinetic facades to familiarize architects and designers with their functions, applications and advantages and for that; after classifying the application of compliant mechanisms in architecture in two levels (the first level is to replace compliant mechanisms with rigid ones and the second one, designing an integrative mechanism), Here, the focus is on first level. In the first level, developed structures are designed in a rigid-body mechanism in which compliant joints replace with mechanical joints, which lead to simplicity in construction and maintenance. The achievement of this level, which has been considered in three subcategories (Translational, rotational, translational-rotational movements in compliant joints) by means of simulation method, is design, computational simulation and construction of three physical models of kinetic skins with compliant joints. Through these models, most benefits of compliant structures such as structural integrity, reduction in member numbers and structure weight, significant reduction in joints’ tension, cost of repair and maintenance and finally, economic justification of plan can have been achieved. In the second level, integrated flexible mechanisms were considered, most of which are difficult to design and need nonlinear equation analysis. Nature, plants in particular, as an inspirational source in the design of these mechanisms have been studied, so that by exploring the rules of motion in the tested plants and transferring them to kinetic structures in architecture, to achieve greater reliability and less complexity, these structures were achieved. | ||
کلیدواژهها [English] | ||
Kinetic Building Skins, Compliant Mechanisms, Rigid-Body Mechanisms, Bi-Stable Compliant Mechanisms | ||
مراجع | ||
متینی، محمدرضا (1394)، بهرهگیری از الگوهای طبیعت برای طراحی ساختارهای تغییرپذیر خمشو در معماری، نشریه هنرهای زیبا-معماری و شهرسازی، دوره 20، شماره 1، صص 67-80. Burry M (2003), Between Surface and Substance, Architectural Design, Surface Consciousness, Vol. 73, No. 2, pp. 8-19.
Chun, M.K (2007), Investigation into the Cause of Pneumatic Actuator Failure on the HypoSurface, BSc thesis, Massachusetts Institute of Technology.
Compliant Mechanisms Research; Brigham young university (2015), http://compliantmechanisms.byu.edu/content/intro-compliant-mechanisms.
Cromvik C. (2007), Numerical Folding of Airbags Based on Optimization and Origami, Master’s thesis, Chalmers University of Technology and G¨oteborg University, Sweden.
Demaine E & O’Rourke J (2007), Geometric Folding Algorithms, Cambridge University Press, ????.
Deshmukha, Bhagyesh; Pardeshib, Sujit; Mistryc, Roohshad; Kandharkard, Sachin & Waghe Santosh (2014), Development of a Four bar Compliant Mechanism using Pseudo Rigid Body Model (PRBM), Procedia Material Science, Vol.6, pp. 1034-1039.
Elkhayat, Youssef Osama (2014), Interactive Movement In Kinetic Architecture, Journal of Engineering Sciences, Vol. 42, No.3, pp.816-845.
Golabchi M. R & Guest S. D (2009), Morphing Multistable Textured Shells, Proc. Proceedings of the International Association for Shell and Spatial Structures (IASS) Symposium, Valencia. Evolution and Trends in Design, Analysis and Construction of Shell and Spatial Structures.
Greenberg, H. C; Gong, M. L; Howell, L. L & Magleby, S. P (2011), Origami and Compliant Mechanisms, Conference Paper: Second International Symposium on Compliant Mechanisms at Delft, The Netherlands, pp.1-7.
Grosso, A. E & Del, Basso P (2010), Adaptive Building Skin Structures, Smart Materials and Structures, Vol.19, No.12, pp.1-12.
Howell Larry, L (2001), Compliant Mechanisms, John Wiley and Sons, New York.
Howell, Larry; L, Spencer; P, Magleby & Brian M. Olsen (2013), Handbook of Compliant Mechanisms, A John Wiley & Sonrs, Ltd., Publication.
Jacobsen, Joseph; O, Larry; L, Howell, Spencer & P. Magleby (2007), Components for the Design of Lamina Emergent Mechanisms, ASME 2007 International Mechanical Congress and Exposition, Mechanics of Solids and Structures, Vol.10, pp.165-174.
Jensen, Brian; D, Larry & L, Howell (2004), Bistable Configurations of Compliant Mechanisms Modeled Using Four Links and Translational Joints, Journal of Mechanical Design, Vol.126, Issue 4, pp.657-666.
Knippers, Jan & Tomas, Speck (2012), Design and construction principles in nature and architecture, IOPscience, Bioinspiration & Biomimetics, Volume7, No.1, pp. ?????.
Lienhard, Julian (2014), Bending-Active Structures, Form-finding Strategies Using Elastic Deformation in Static and Kinetic Systems and The Structural Potentials Therein, Doctoral Dissertation in Stuttgart University, ITKE.
Megahed, Naglaa Ali (2017), Understanding Kinetic Architecture: Typology, Classification, and Design Strategy, Architectural Engineering and Design Management, Vol.13, Issue2, pp.?????.
Milojevic, Andrija (2011), Compliant bistable mechanisms, Conference Paper at Kraljevo, Serbia, June 2011, pp. 181-186. Moloney, Jules (2011), Designing Kinetics for Architectural Facades, Routledge Taylor & Francis Group, London and New York.
Sample, H (2012), A Brise-Soleil without a Building, In Matter: Material Processes in Architectural Production; Edited by Borden G.P. & Meredith M., Routledge, Oxon, pp. 329-339.
Schittich, C (2001), In Detail: Building Skins—Concepts, Layers, Materials, Birkhauser, Basel.
Sharaidin, Kamil (2014), Kinitic Façade: Towards design for Environmental Performance, Presented to the School of Architecture and Design RMIT University in Partial Fulfillment of the Requirements for the Degree of Doctor of Philosophy.
Ritter, Axel (2007), Smart Materials in Architectur; InteriorArchitecture and Design, Birkhauser Publication, Basel, Berlin, Boston.
Schleicher, Simon; Julian, Lienhard; Simon, Poppinga; Thomas, Speck & Jan, Knippers (2014), A Methodology for Transferring Principles of Plant Movements to Elastic Systems in Architecture, Computer-Aided Design, Vol.60, pp.105-117.
Tachi, T (2010), Rigid-Foldable Thick Origami, in: Origami 5: The 5th International Conference on Origami in Science Mathematics and Education, ?????.
PEI, Xu; YU, Jingjun; ZONG, Guanghua & BI, Shusheng (2014), Design of Compliant Straight-line Mechanisms Using Flexural Joints, Chinese Journal of Mechanical Engineering, Vol. 27, No. 1, pp. 146-153.
| ||
آمار تعداد مشاهده مقاله: 1,579 تعداد دریافت فایل اصل مقاله: 2,875 |